DE102004030815B4 - Connection system for mechanical connection of components - Google Patents

Abstract

Connection system (10) for fastening a first component (20) to a second component (30), the
i. a first dowel (60) having a first dowel inner hole (80) with at least one first dowel inner hole axis, which is fastened in a first blind hole (40) with a first hole axis,
ii. a second dowel (70) having a second dowel inner hole (90) with at least one second dowel inner hole axis which is fastened in a second blind hole (50) with a second hole axis in a second component (30),
iii. between the first dowel (60) and the second dowel (70), a sleeve (100, 1040) having an inner sleeve radius and an outer sleeve radius, and
iv. a pin (110, 800, 910, 920, 1050) insertable in the sleeve (100) with a pin radius
includes.

Description

FIELD OF THE INVENTION

The The invention relates to a connection system for mechanical Connection of at least two components.

BACKGROUND OF THE INVENTION

In The connection technology is a variety of connection systems z. B. for connecting components such as natural or artificial stones and straps made of wood or metal.

At the House building become load-bearing walls often made of bricks connected with cement mortar. The result is a rigidly connected wall that is relatively inelastic is. The inelasticity the connection makes such walls susceptible for vibrations and shakes z. B. an earthquake.

Of the Construction mortared brick walls includes, in addition for laying up the bricks, a step of preparation the mortar, a step of applying the mortar to the bricks and a step of setting the mortar during which the compound the components is formed. The step of applying the mortar must be carried out within a certain period of time after the preparation of the mortar before the mortar begins to bind. The layering of bricks is on one limited number of rows before further rows of Bricks on the bricks connected by the hardened mortar are, can be piled up. This causes delays due to breaks during construction.

environmental conditions limit the processing of the mortar also a, z. B. is the typical processing temperature of cement mortar above 5 ° C. Temperatures below 0 ° C are a problem because the water that is commonly used for the preparation of the mortar is frozen. additionally can also increased Temperatures and humidity the properties and processing certain mortar influence.

The Location of each brick is determined by the positioning Stratifying determined. Therefore, to achieve an accurate Wall, a certain craft skill necessary and expensive, trained workers are needed.

The Components of internal and / or non-load-bearing walls are nowadays often connected with adhesive. For the processing of adhesive apply similar restrictions as discussed above in connection with the processing of mortar.

Especially There are a number of systems for interior walls in the do-it-yourself area Positioning devices that help the components relative to position each other. Such positioning devices, z. B. tongue and groove systems must attached to the components in their manufacture. On a construction site can the complete, molded components then joined together and z. B. be connected with adhesive.

State of the art

Adhesive-free Compounds of components are z. B. from the field of wood joints known. A variety of different pin connections is z. B. from the carpentry trade, such. B. the dovetail connection, which allows an interlocking connection of two components.

The use of kebstoff-free dowel joints is also known for wooden components. The German patent DE 1 107 910 teaches a connection of two components, which is produced by a flexible dowel. The flexible dowel is inserted in two holes in two components. The axes of the holes are slightly inclined relative to the normal of the device surfaces. The holes in the components form an obtuse angle when the components are compressed and the dowel is bent according to this obtuse angle. Preferably, two or more dowels are used. The inclination of the hole axis to the surface points in a direction other than the inclination of the associated hole axis of the hole in the adjacent component. The teachings of the '910 patent are limited to wood and woody materials. Specifically, the '910 patent addresses the problem of airlocks between the dowel and the hole which, as the ambient temperature increases, may cause the connection to explode explosively due to the expansion of this trapped air. The '910 patent describes a method of how this solution of the connection can be prevented by milling in the dowel.

helical Connection systems are very universally applicable. A problem with such connection systems accessibility to the screw head and mother, z. When a plurality of rows of components, such as As building blocks, is joined together to form a wall. The bottom of a building block is, after fixing the row, no longer easily accessible. Another problem is the random one Loosen screw-type connections. An access to screws, which are inserted along the construction direction of the wall is no longer possible if the wall is finished.

Problems with accessibility to screw head and nut and possible positions for screws have led to solutions as described in the European patent application EP-A-1 389 687 to be discribed. The '687 application teaches a system for mechanical connection of components in which special connectors are attached to the components. The fasteners are fastened to the components with screws before the components are connected. The fasteners provide the teeth when assembling the components, so that after assembly of the components a non-destructive disassembly of the components is almost impossible. Such systems can, as in the German patent DE-A-100 26769 described used in the construction of prefabricated houses. The '769 patent teaches the use of such fasteners for buildings with both long and medium term use, e.g. For emergency shelters after earthquakes or military buildings. The patent emphasizes advantages in construction time, cost, and the ability to build houses with poorly trained workers, as opposed to methods such as the construction of brick walls using mortar.

adversely for the in the '769 patents and '687 described Systems is that both additional fasteners Add to the components. These fasteners themselves are rather complicated.

Another approach for a mortar-free method for the construction of brick walls is a screw-type connection system for building systems, as described in the European patent application EP-A-1 382 761 is described. Starting from problems similar to the '769 patent, the' 761 patent teaches a connection system in which, starting on a base plate, the individual bricks are connected to and with screws with the row of bricks underneath and above. In one embodiment, upper attachment means have a lower female thread. Lower fasteners begin in the base plate and have a length of somewhat the brick height and have a male upper thread. The bricks have holes that are adapted for the lower fastening means of the fastening system. When layering a row, the lower fasteners are passed through the holes of the bricks. The upper attachment means are screwed onto the lower attachment means. The upper part of the upper attachment means is designed such that it can serve as the lower attachment means for the next row. The '761 application describes a system that allows the non-destructive disassembly and reassembly of components. In preferred embodiments, the '761 application describes positioning devices to hold the bricks in place. The application 761 is aimed at brick walls for facades on houses with wooden frame construction. There is no information about the load capacity of the walls.

From the German patent application DE 24 37 308 is a connection system, ie a fastening device for attaching lightweight panels or the like on walls or ceilings known. The fastening device here consists of an anchor device for the lightweight panels and an associated expansion dowel, which can be introduced into a correspondingly long wall hole to securely attach the lightweight panels to the wall by the anchor device. The anchor device in this case consists of a flattened, mushroom-shaped anchor head with an opening and a neck sleeve and an intermediate sleeve, which in the installed (collapsed) state of loading fastening device is largely included within the neck sleeve. The expansion anchor comprises a dowel bore running in the longitudinal direction of the expansion anchor. The opening of the anchor bore is provided with a chamfer, so that a drivable in the expansible plug cylindrical expansion pin can be easily inserted. When assembling the neck sleeve, the intermediate sleeve and the expander pin telescopically pushed until the one edge of the neck sleeve and the dowel-side edge of the intermediate sleeve to annular order abut stops of the expansion pin against each other. In other words, this publication teaches an anchor / dowel fastening device comprising two sleeves and a pin, in which, in the assembled state, the sleeves of the anchor are shifted into one another in order to meet different wall thicknesses of lightweight panels.

OBJECT OF THE INVENTION

It is therefore an object of the invention, an improved, versatile usable, stable connection system for various types of components to disposal to deliver.

It Another object is to allow a connection of components, which allows an elastic movement of the components against each other.

It It is another object of the invention to provide a connection system that a fast and efficient construction of buildings, such. B. houses, even under difficult environmental conditions, available to put.

These and other tasks are accomplished by providing a connection system for fastening a first component to a second component solved. The connection system comprises a first dowel with a first dowel inner hole with a first dowel inner hole axis, the fastened in a first hole or blind hole with a first Hole axis is inserted in a first component, and a second Dowel with a second dowel hole with a second dowel inner hole axis, the fastened in a second hole or blind hole with a second Hole axis is inserted in a second component. A sleeve with an inner and an outer sleeve radius is between the dowels in the first dowel hole and the second dowel hole plugged. A pin with a pin radius is inserted into the sleeve.

The Use of a connection system according to the invention allows the connection of components of a variety of types of materials that allow sufficiently stable drill holes. The materials for the dowel, the Sleeve and the pen can in their structure, e.g. B. the surface structure can be adjusted. The materials for the dowel, the sleeve and the pen can also in their properties, such. B. elasticity, to the materials, from which the components consist. The typical diameter the holes lies in an area that allows efficient drilling of holes in allowed the materials of the components.

The Movement of interconnected components against each other mainly determined by the elastic properties of the compound since the connection between the components only through the connection systems arises at certain points, and additionally by the frictional forces of the between the connected components. In particular, the elastic properties of these compounds related to the materials used for the connection systems are set. This is the construction of a non-stiff wall possible, especially for building in earthquake-prone Areas is suitable.

To build with the disclosed connection system is ambient temperature independently. The components can before transport to a construction site or directly at the construction site with holes be provided. The assembly of the components can be unskilled labor carried out become. Waiting for the curing of the mortar deleted.

The Connection can z. B. by bending the pin and the sleeve in one obtuse angles are formed. The resulting elastic personnel and plastic deformations in the connection system interlock the Connection system together with the components.

The Connection can be made by deformation of the sleeve and the pin by a eccentricity an upper dowel axis against a lower dowel axis be formed. As a result, the sleeve and the pin against the anchor wall pressed and tilt the entire connection system with the components.

The Compound can be formed by deformations and tension, by non-conformity the dowel inner hole axes of the installed first dowel with the dowel inner hole axes of the second dowel is caused.

The compound can be formed by deformations and tensions, the z. B. by Zu Compression of sleeve, dowel and pin, z. B. arise when inserting the pin into a tapered dowel inner hole when z. B. the pin has a larger diameter than the tapered Dübelinnenloch at the appropriate insertion depth.

DESCRIPTION OF THE FIGURES

1 shows a connection system according to the invention in decomposed form

2a shows two two-piece dowels for the connection system

2 B shows the dowel shell 2a

2c shows the dowel base 2a

3 shows a connection system in composite form

4 shows another example of a compound system in compound form

5 shows an example of a dowel according to the invention

6 shows a further example of a dowel according to the invention

7 shows a further example of a dowel according to the invention

8th shows an example of a sleeve according to the invention

9a shows an example of a pen according to the invention

9b shows another example of a pen according to the invention

9c shows two further examples of a pen according to the invention

10 shows four components connected according to the invention

11 shows a wall construction with use of the connection system of the invention

12 shows a building constructed using the connection system of the invention

13 shows a variety of connections with the connection system according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

1 shows a connection system 10 the invention in disassembled form. A first component 20 intended with a second component 30 get connected. The first component 20 and the second component 30 may be any building materials, including, but not limited to, stone, tile, concrete or wood. A first hole 40 is in the first component 20 drilled and a second hole 50 is in the second component 30 drilled. A first dowel 60 is in the first hole 40 stuck and a second dowel 70 is in the second hole 50 plugged. The first dowel 60 has a first dowel hole 80 and the second dowel 70 has a second dowel hole 90 ,

In a preferred embodiment of the invention, the first dowel 60 and the second dowel 70 divided into two areas. The first dowel 60 has a first dowel shell 62 and a first dowel base 64 , The first dowel shell 62 closes to the surface of the first component 20 on and the first dowel base 64 is within the first device 20 , The first dowel shell 62 and the first dowel base 64 are over a ko nisch running intermediate piece 66 connected. The dowel inner diameter of the first dowel shell 62 is larger than the dowel inner diameter of the first dowel base 64 ,

In the same way, the second dowel has 70 a second dowel shell 72 and a second dowel base 74 , The second dowel shell 72 closes to the surface of the second component 30 on and the second dowel base 74 is within the second device 30 , The second dowel shell 72 and the two te dowel base 74 are over a conical intermediate piece 76 connected. The dowel inner diameter of the second dowel shell 72 is larger than the dowel inner diameter of the second dowel base 74 ,

The length of the first dowel shell 62 and the second dowel shell 72 are essentially the same and are in 1 denoted by D. The depth of the first hole 40 and the second hole 50 are also substantially the same and designated C.

A sleeve 100 is in the first dowel hole 80 plugged to a depth of about 1 / 3D and a pen 110 is in the second hole 50 plugged in. The sleeve 100 is typically designed as a hollow cylinder. The pencil 110 can z. B. be designed as a hollow cylinder or as a solid cylinder.

In an exemplary embodiment of the invention, the first component 20 and the second component 30 Concrete slabs. The first dowel 60 and the second dowel 70 are made of plastic or silicate polymer. A plastic such. B. polyethylene can be z. B. silicate particles are added to form a Silikatarmierung. The first dowel 60 and the second dowel 70 may also be provided with a ceramic coating for improved bonding. By this ceramic coating or Silikatarmierung z. B. the friction between the relevant components 20 and 30 , the relevant dowels 60 and 70 , and the relevant sleeve 100 and the relevant pen 110 increase.

The first dowel shell 62 and the second dowel shell 72 have a length of 120 mm, a dowel hole diameter of 25.8 mm and a dowel outer diameter of 49.6 mm. The first dowel base 64 and the second dowel base 74 have a length of 80 mm, a dowel inner diameter of 20.2 mm and a dowel outer diameter of 49.6 mm. The pencil 110 is made of steel St37 with a length of 398 mm and a diameter of 19 mm. The first hole 40 and the second hole 50 have a hole diameter of 50 mm and a depth of 200 mm.

The sleeve 100 is made of steel St37 with a sleeve inner diameter of 19.8 mm, a sleeve outer diameter of 25 mm and a length of 238 mm. These dimensions are only exemplary and the invention is not limited to these dimensions.

In one embodiment of the invention, the first dowel 60 and the second dowel 70 made in one piece. In another embodiment of the invention, the first dowel 60 and the second dowel 70 made of two pieces, according to the dowel tops 62 and 72 and the dowel bases 64 and 74 , The two-piece dowel may be easier to manufacture from a manufacturing point of view.

2a shows a further embodiment of the invention, in which both the first dowel 60 as well as the second dowel 70 are made in two parts. In this embodiment of the invention, the first dowel 60 in a first dowel shell 62 with a first upper dowel hole 82 and a first dowel base 64 with a first lower dowel hole 84 divided and the first dowel shell 62 and the first dowel base 64 are each designed as individual workpieces. In the same way are the second dowel 70 in a second dowel shell 72 with a second upper dowel hole 92 and a second dowel base 74 with a second lower dowel hole 94 divided and the second dowel shell 72 and the second dowel base 74 are each designed as individual workpieces. The first dowel shell 62 and the second dowel shell 62 are each 54 mm long with an outer diameter of 44 mm and a dowel inner diameter of 21.5 mm. The first dowel base 64 and the second dowel base 74 are 36 mm long with an outer diameter of 44 mm and a dowel inner diameter of 18 mm. The dowel hole 82 of the first dowel shell 62 and the dowel hole 84 of the first dowel base 64 are not coaxial in this embodiment of the invention, ie the Dübelinnenlochachse 63 of the first dowel shell 62 and the dowel inner hole axis 65 of the first dowel base 64 are shifted against each other and the Dübellinnenlochachse 63 of the first dowel shell 62 and the dowel inner hole axis 65 of the first dowel base 64 are eccentric. In the same way are the dowel hole 92 of the second dowel shell 72 and the dowel hole 94 of the second dowel base 84 not coaxial in this embodiment of the invention, ie the Dübelinnenlochachse 73 of the second dowel shell 72 and the dowel inner hole axis 75 of the second dowel base 74 are shifted against each other and the Dübellinnenlochachsen 73 . 75 are eccentric. For example, the Dübelinnenlochachse 63 of the first dowel shell 62 and the dowel inner hole axis 73 of the second dowel shell 72 or the Dübelinnenlochachse 65 of the first dowel shell 64 and the dowel inner hole axis 75 second dowel base 74 be displaced by about 1 mm against the respective dowel axes of the workpieces, which coincide with the axes of the holes. The first dowel shell 72 is against the first dowel base 62 or the second anchor shell 74 against the second dowel base 72 then to Connection with the eccentricities against each other z. B. twisted by 15 ° in the first hole 40 or in the second hole 50 , The eccentricities of the first dowel 60 can then additionally against the eccentricities of the second anchor 70 be installed twisted. For the material of the first dowel 60 and the second dowel 70 For example, polyethylene with about 8.9 weight percent silicate particles can be used. The connection system 10 will be together with a pen 110 made of steel with a length of 180 mm and a diameter of 18 mm and a sleeve 100 made of steel with a sleeve inner diameter of 18 mm, a sleeve outer diameter of 21.5 mm and a length of 108 mm.

In 2 B is the dowel shell 230 that the dome tops 62 . 72 out 2a corresponds individually to the first or second dowel. In 2c is the dowel base 220 that the dowels 64 . 74 out 2a corresponds individually to the first or second dowel. In the illustrated embodiment, the dowel base is 220 with feathers 232 provided in the grooves 222 of the dowel shell 230 can engage and so twisting the dowels shells 230 against the dowel bases 220 prevent.

3 shows the connection system 10 out 1 in composite form. The pencil 110 is completely in the sleeve 100 plugged in. The pencil 110 and the sleeve 100 are held in this position by forces (F) by the first dowel 60 and the second dowel 70 on the sleeve 100 be exercised.

4 shows an embodiment of the invention in which the Dübelinnenlochachse 63 of the first dowel shell 62 and the dowel inner hole axis 65 of the first dowel base 64 and the Dübelinnenlochachse 73 of the second dowel shell 72 and the dowel inner hole axis 75 of the second dowel base 74 are not formed coaxially. In this way, a greater force is applied to the sleeve 100 exercised.

Other embodiments of the connection system are in the 5 - 7 shown. They use for the material of the first dowel 60 and the second dowel 70 Polyethylene with about 8.9 weight percent silicate particles. The pencil 110 (as an example separately in 9a shown) is made of steel with a length of 180 mm and a diameter of 18 mm. The sleeve 100 (as an example separately in 8th shown) is made of steel with a sleeve inner diameter of 18 mm, a sleeve outer diameter of 21.5 mm and a length of 108 mm. The first dowel 60 and the second dowel 70 each include a dowel shell 62 . 72 and a dowel base 64 . 74 , The first dowel base 64 and the second dowel base 74 each include barbs 240 , barb 240 can z. B. as 3 mm thick, 6 mm wide rods with a length of 33 mm from the first dowel base 64 and the second dowel base 74 protrude. For this connection system 10 There are now different configurations of the first anchor 60 and the second dowel 70 :

1st example ( 5 ):

The dowel shell 230 has a length of 55 mm, a conically tapered from 24 mm to 21.5 mm Dübelinnenlochdurchmesser 250 , which then remains on a further length of 11 mm at a constant value of 21.5 mm and a dowel outer diameter of 44 mm. The dowel base 220 has a length of 33 mm, a conical from 19 mm to 18 mm tapered Dübelinnenlochdurchmesser 225 and a dowel outer diameter of 44 mm. The transition between the dowel shell 230 and the dowel base 220 is via a conical intermediate piece 255 implemented on a length of about 1 mm. The dowel base 220 may be slashed.

2nd example ( 6 ):

The dowel shell 310 has a length of 55 mm, a Dübelinnenlochdurchmesser 315 of 24 mm and a dowel outer diameter of 44 mm. The dowel base 320 has a length of 33 mm, a Dübelinnenlochdurchmesser 325 of 18 mm and a dowel outer diameter of 44 mm. The transition between the dowel shell 310 and the dowel base 320 is via a conical intermediate piece 330 implemented on a length of about 3 mm. The dowel inner hole axis 301 of the dowel base 320 is about 2 mm against the Dübelinnenlochachse 316 of the dowel shell 310 corresponding to the dowel axis coinciding with the hole axis in this embodiment. The position of the axes is shown in the cross section drawing in 6 illustrated.

Third Example:

With the masses of the dowel 200 from the first example ( 5 ) is the dowel hole 415 of the dowel shell 410 and the dowel hole 425 of the dowel base 420 eccentric against the dowel 400 ver puts. Ie. the common axis 416 an upper dowel inner hole 415 and a lower dowel inner hole 425 is for example about 2 mm against the dowel axis 401 offset, as in the cross-sectional drawing of 7 is illustrated. Will this dowel 400 used in the connection system according to the invention, the dowel axis falls 401 with the hole axis together. When using the embodiment of the anchor 400 as the first dowel 60 and as a second dowel 70 are the first dowel 60 and the second dowel 70 twisted by 15 ° relative to each other to form the joint, ie with misalignment of the eccentricities of the common axis 416 in the first dowel 60 and the common axis 416 in the second dowel 70 , put in the first and second hole.

Three other embodiments of the pen are in 9b and c. In the embodiment of the 9c has a pen 110 a change 810 as in the detailed representation in 9c is shown. The pencil 110 has an outer diameter of 18 mm. The depth (3.5 mm) of the change 810 is greater than the eccentricity of Dübelinnenlochachsen the associated dowel 60 . 70 , Two embodiments of the pen 110 are in 9b shown. Both embodiments of the pen 910 and 920 have longitudinal grooves on the surface of the pin. In one embodiment of the pen 910 these are longitudinal grooves 930 deep in another embodiment of the pen 920 these are longitudinal grooves 930 flat.

10 shows a system 1000 , the two components 1010 and 1020 with pre-assembled dowels 1030 , Pods 1040 and pins 1050 includes. The dowels 1030 , Pods 1040 and pins 1040 can in one of the components 1010 and 1020 be attached in advance - z. B. in the factory for the components - and the components 1010 . 1020 can then be quickly assembled at the construction site.

Another version of the system 1000 is in 11 displayed. A wall is made up of a plurality of components 1110 constructed, with dowels, pins and sleeves - together with 1120 in this example - on the components 1110 are pre-assembled.

A house - or another type of building - is in 12 displayed. Various examples of the connection of components 1210 with connection systems according to the invention are shown. 13 shows the in 12 enlarged connections shown. List of reference numbers 10 connection system 20 First component 30 Second component 40 First hole 50 Second hole 60 First dowel 62 First dowel shell 63 Dowel inner hole axis of the first dowel shell 64 First dowel base 65 Dowel inner hole axis of the first dowel base 66 connecting piece 70 Second dowel 72 Second dowel shell 73 Dowel inner hole axis of the second dowel shell 74 Second dowel base 75 Dowel inner hole axis of the second dowel base 76 connecting piece 80 First dowel hole 82 First upper dowel hole 84 First lower dowel hole 90 Second dowel hole 92 Second upper dowel hole 94 Second lower dowel hole 100 shell 110 pen 200 dowel 220 Dowel base 222 groove 225 Dowel hole diameter of the dowel base 230 Dowel shell 232 feather 240 barb 250 Dowel hole diameter of the dowel shell 255 connecting piece 300 dowel 301 Dowel pin hole axis of the dowel base 310 Dowel shell 315 Dowel hole diameter of the dowel shell 316 Dowel pin hole axis of the dowel shell 320 Dowel base 325 Dowel hole diameter of the dowel base 330 connecting piece 400 dowel 401 anchor axis 410 Dowel shell 415 Dowel inner hole of the dowel shell 416 Common axis 420 Dowel base 425 Dowel inner hole of the dowel shell 450 hole 800 pen 810 Ränderung 910 pen 920 pen 930 longitudinal grooves 1000 system 1010 module 1020 module 1030 dowel 1040 shell 1050 pen 1110 module 1120 Dowel, sleeve and pin

Claims (26)

Connection system ( 10 ) for fastening a first component ( 20 ) on a second component ( 30 ), the I. a first dowel ( 60 ) with a first dowel inner hole ( 80 ) with at least one first dowel inner hole axis, which can be fastened in a first blind hole ( 40 ) is used with a first hole axis, ii. a second dowel ( 70 ) with a second dowel inner hole ( 90 ) with at least one second dowel inner hole axis, which can be fastened in a second blind hole ( 50 ) with a second hole axis in a second component ( 30 ), iii. between the first dowel ( 60 ) and the second dowel ( 70 ) a sleeve ( 100 . 1040 ) having an inner sleeve radius and an outer sleeve radius, and iv. a pen ( 110 . 800 . 910 . 920 . 1050 ), which is in the sleeve ( 100 ), with a pin radius. Connection system ( 10 ) according to claim 1, wherein the first and / or second dowel ( 60 . 70 ) a dowel shell ( 62 . 72 . 230 . 310 . 410 ) and a dowel base ( 64 . 74 . 220 . 320 . 420 ), wherein the dowel upper part ( 62 . 72 . 230 . 310 . 410 ) and the dowel base ( 64 . 74 . 220 . 320 . 420 ) before the connection of the first to the second component ( 20 . 30 ) form a coherent workpiece. Connection system ( 10 ) according to claim 1, wherein the first and / or second dowel ( 60 . 70 ) a dowel shell ( 62 . 72 . 230 . 310 . 410 ) and a dowel base ( 64 . 74 . 220 . 320 . 420 ), wherein the dowel upper part ( 62 . 72 . 230 . 310 . 410 ) and the dowel base ( 64 . 74 . 220 . 320 . 420 ) before the connection of the first to the second component ( 20 . 30 ) are separate workpieces. Connection system ( 10 ) according to claim 1 to 3, wherein the dowel inner hole ( 415 ) of the first dowel shell ( 62 ) and / or the second dowel shell ( 72 ) and / or the dowel inner hole ( 425 ) of the first dowel part ( 64 ) and / or the second dowel base ( 74 ) tapers conically over at least portions of the length. Connection system ( 10 ) according to claim 1, wherein the dowel inner hole ( 80 . 90 ) of the first anchor ( 60 ) and / or the second anchor ( 70 ) an upper dowel inner hole ( 82 . 92 ) in the upper dowel part ( 62 . 72 ) with an upper dowel inner hole radius and an upper dowel inner hole axis ( 63 . 73 ) and a lower dowel hole ( 84 . 94 ) in the lower dowel part ( 64 . 74 ) with a lower dowel inner hole radius and a lower dowel inner hole axis ( 65 . 75 ), wherein the upper dowel inner hole radius is larger than the lower dowel inner hole radius. Connection system ( 10 ) according to claim 4, wherein the upper dowel inner hole axis ( 63 ) and the lower dowel inner hole axis ( 65 ) of the first anchor ( 60 ) with the axis of the first blind hole ( 40 ) into which the first dowel ( 60 ) is plugged, coincide and / or the upper dowel inner hole axis ( 73 ) and the lower dowel inner hole axis ( 75 ) of the second anchor ( 70 ) with the axis of the second blind hole ( 50 ) into which the second dowel ( 70 ), coincide. Connection system ( 10 ) according to claim 4, wherein the upper dowel inner hole axis ( 63 ) and / or the lower dowel inner hole axis ( 65 ) of the first ( 60 ) Dowel slightly eccentric with respect to the axis of the first blind hole ( 40 ) into which the first dowel ( 60 ) are plugged and / or the upper Dübelinnenlochachse ( 73 ) and / or the lower dowel inner hole axis ( 75 ) of the second anchor ( 70 ) slightly eccentric relative to the axis of the second blind hole ( 50 ) into which the second dowel ( 70 ) are plugged. Connection system ( 10 ) according to one of claims 4 or 6, wherein the upper dowel inner axis ( 63 ) and the lower dowel inner hole axis ( 65 ) of the first anchor ( 60 ) coincide and the upper Dübelinnenlochachse ( 63 ) and the lower dowel inner hole axis ( 65 ) of the first anchor ( 60 ) slightly eccentric to the axis of the first blind hole ( 40 ) into which the first dowel ( 60 ) is plugged, and / or the upper Dübelinnenlochachse ( 73 ) and the lower dowel inner hole axis ( 75 ) of the second anchor ( 70 ) coincide and the upper Dübelinnenlochachse ( 73 ) and the lower dowel inner hole axis ( 75 ) of the second anchor ( 70 ) slightly eccentric to the axis of the second blind hole ( 50 ) into which the second dowel ( 70 ) are plugged. Connection system ( 10 ) according to claim 4, wherein the upper dowel inner axis ( 63 ) of the first anchor ( 60 ) and the axis of the first blind hole ( 40 ) into which the first dowel ( 60 ), coincide and the lower dowel inner hole axis ( 65 ) of the first anchor ( 60 ) eccentric to the upper dowel inner hole axis ( 63 ) of the first anchor ( 60 ) and the axis of the first blind hole ( 40 ) and / or the upper dowel inner axis ( 73 ) of the second anchor ( 70 ) and the axis of the second blind hole ( 50 ), in which the two te dowels ( 70 ), coincide and the lower dowel inner hole axis ( 75 ) of the second anchor ( 70 ) eccentric to the upper dowel inner hole axis ( 73 ) of the second anchor ( 70 ) and the axis of the second blind hole ( 50 ). Connection system ( 10 ) according to claim 1, wherein the dowel inner hole axis ( 63 ) of the first anchor ( 60 ) slightly inclined to a normal on a surface around the first blind hole ( 40 ) in the first component ( 20 ) into which the first dowel ( 60 ) is introduced, and / or the dowel inner hole axis ( 73 ) of the second anchor ( 70 ) slightly inclined to a normal on a surface around the second blind hole ( 50 ) in the second component ( 30 ) into which the second dowel ( 70 ) is introduced. Connection system ( 10 ) according to claim 9, wherein the axis of the first blind hole ( 40 ) in the first component ( 20 ) slightly inclined to the normal on the surface around the first blind hole ( 40 ) in the first component ( 20 ) is in which the first dowel ( 60 ) and / or the axis of the second blind hole ( 50 ) in the second component ( 30 ) slightly inclined to the normal on the surface around the second blind hole ( 50 ) in the second component ( 30 ) is in which the second dowel ( 70 ) is introduced. Connection system ( 10 ) according to claim 9, wherein the first dowel inner hole axis ( 63 ) slightly inclined to the axis of the first blind hole ( 40 ) in the first component ( 20 ), in which the first dowel ( 60 ) is plugged and / or the second Dübelinnenlochachse ( 73 ) slightly inclined to the axis of the second blind hole ( 50 ) in the second component ( 30 ), in which the second dowel ( 70 ) is plugged. Connection system ( 10 ) according to one of the preceding claims, wherein the first and / or the second dowel ( 60 . 70 ) Barbs ( 240 ). Connection system ( 10 ) according to one of the preceding claims, in which one or more sleeves ( 100 . 1040 ) are made of wood, plastic or metal. Connection system ( 10 ) according to one of the preceding claims, in which one or more sleeves ( 100 . 1040 ) are made of steel. Connection system ( 10 ) according to one of the preceding claims, in which one or more pins ( 110 . 800 . 910 . 920 . 1050 ) are made of wood, plastic or metal. Connection system ( 10 ) according to claim 16, wherein one or more pins ( 110 . 800 . 910 . 920 . 1050 ) are made of steel. Connection system ( 10 ) according to one of the preceding claims, in which one or more dowels ( 60 . 70 . 200 . 300 . 400 . 1030 ) are made of wood, plastic or metal. Connection system ( 10 ) according to claim 18, wherein one or more dowels ( 60 . 70 . 200 . 300 . 400 . 1030 ) are made of polyethylene. Connection system ( 10 ) according to claim 18, wherein one or more dowels ( 60 . 70 . 200 . 300 . 400 ) are made of polyethylene and the dowel ( 60 . 70 . 200 . 300 . 400 ) Comprises silicate particles. Dowels ( 60 . 70 . 200 . 300 . 400 . 1030 ) for use in a connection system ( 10 ) according to one of claims 1 to 20. Sleeve ( 100 . 1040 ) for use in a connection system ( 10 ) according to one of claims 1 to 20. Pen ( 110 . 800 . 910 . 920 . 1050 ) for use in a connection system ( 10 ) according to one of claims 1 to 20. Connection of components ( 20 . 30 . 1010 . 1020 . 1110 ) by a plurality of connection systems ( 10 ) according to one of claims 1 to 20. Connection of components ( 20 . 30 . 1010 . 1020 . 1110 ) by a plurality of connection systems ( 10 ) according to claim 24, wherein the connection systems ( 10 ) are twisted against each other. Construction that is a first building element ( 20 ) and a second component ( 30 ), wherein the first component ( 20 ) and the second component ( 30 ) of one or more connection systems ( 10 ) are held together according to one of claims 1 to 20.